2344-70-9

Basic information

• Product Name: 4-Phenyl-2-butanol
• Synonyms: 4-Phenylbutan-2-ol;alpha-methyl-benzenepropano;AURORA KA-6974;FEMA 2879;ALPHA-METHYL-BENZENEPROPANOL;(+/-)-4-PHENYL-2-BUTANOL;4-PHENYL-2-BUTANOL;PHENYLETHYL METHYL CARBINOL
• CAS NO: 2344-70-9
• Molecular Formula: C₁₀H₁₄O
• Molecular Weight: 150.22
• EINECS: 219-055-9
• Mol File: 2344-70-9.mol
• Article Data: 560

Chemical Properties

• Melting Point: 61 °C
• Boiling Point: 132 °C14 mm Hg(lit.)
• Flash Point: 231 °F
• Appearance: /liquid
• Density: 0.970 g/mL at 25 °C(lit.)
• Vapor Pressure: 0.0147mmHg at 25°C
• Refractive Index: n20/D 1.5140(lit.)
• Storage Temp.: Sealed in dry,Room Temperature
• PKA: 15.10±0.20(Predicted)
• BRN: 1908294
• CAS DataBase Reference: 4-Phenyl-2-butanol(CAS DataBase Reference)
• NIST Chemistry Reference: 4-Phenyl-2-butanol(2344-70-9)
• EPA Substance Registry System: 4-Phenyl-2-butanol(2344-70-9)

Safety Data

• Safety Statements: 24/25
• WGK Germany: 3
• Hazardous Substances Data: 2344-70-9(Hazardous Substances Data)

Usage

Description

4-Phenyl-2-butanol is a clear, colorless liquid with a herbaceous, aromatic, floral-fruity odor. It is a versatile compound that can undergo racemization efficiently at room temperature in the presence of a base, such as (η5-pentaphenylcyclopentadienyl)RuCl(CO)2. Additionally, it can react with sulfuric acid to yield polymers.

Uses

1. Used in Chemical Synthesis:
4-Phenyl-2-butanol is used as a reagent for the direct alkylation of amines with primary and secondary alcohols through biocatalytic hydrogen borrowing. This application takes advantage of its chemical properties to facilitate specific reactions in the synthesis of various compounds.
2. Used in Personal Care Industry:
4-Phenyl-2-butanol is used as a component in the preparation of personal care compositions, particularly those that comprise malodor reduction compositions. Its aromatic, floral-fruity odor makes it a suitable ingredient for creating pleasant scents in personal care products.
3. Used in Polymer Production:
When 4-Phenyl-2-butanol reacts with sulfuric acid, it yields polymers. This property can be utilized in the polymer industry to create new materials with specific properties, such as enhanced strength or flexibility, depending on the desired application.

Preparation

The optically inactive product can be prepared by hydrogenation of benzylidene acetone in alcohol solution; under pressure in the presence of platinum oxide, palladium oxide or ferrous sulfate; by reduction with magnesium in methanol.

Synthesis Reference(s)

Tetrahedron Letters, 30, p. 6461, 1989 DOI: 10.1016/S0040-4039(01)88994-2

InChI:InChI=1/C10H14O/c1-9(11)7-8-10-5-3-2-4-6-10/h2-6,9,11H,7-8H2,1H3/t9-/m1/s1

Upstream product

• 104-53-0 3-phenyl-propionaldehyde 
• 917-64-6 methyl magnesium iodide 
• 75-16-1 methylmagnesium bromide 
• 2550-26-7 4-Phenyl-2-butanone 
• 3277-89-2 phenethylmagnesium bromide 
• 75-07-0 acetaldehyde 
• 17488-65-2 (+)-1t-Phenyl-buten-⁽¹⁾-ol-⁽³⁾ 
• 122-57-6 1-Phenylbut-1-en-3-one 
• 1896-62-4 (E)-benzalacetone 
• 2167-39-7 (+/-)-2-methyloxetane 
• 908094-04-2 phenyldiazomethane 
• 67-63-0 isopropyl alcohol 
• 60012-51-3 Phenylsulfonyl-1-phenyl-1-butanol-3 
• 75-56-9 methyloxirane 

Downstream Products

• 96735-17-0 formic acid-(1-methyl-3-phenyl-propyl ester) 
• 10415-88-0 4-phenylbut-2-yl acetate 
• 91244-87-0 Chlormethyl-<4-phenyl-butyl-(2)>-ether 
• 143097-80-7 2-bromo-4-phenylbutane 
• 126745-47-9 N,4-dimethyl-N-(4-phenylbutan-2-yl)benzenesulfonamide 
• 126745-48-0 N-(3-phenyl-1-methyl-propyl)-N'-(ethoxycarbonyl)hydrazinecarboxylic acid ethyl ester 
• 150501-74-9 <3-(Triisopropylsiloxy)butyl>benzene 
• 75178-13-1 4-phenylbutan-2-yl hexanoate 
• 85733-06-8 1-methyl-3-phenylpropyl 2-methylpropionate 
• 130260-31-0 (E)-3-Phenyl-acrylic acid 1-methyl-3-phenyl-propyl ester 
• 126745-55-9 C₂₂H₂₉NO₄S 
• 101196-33-2 1-(1-Methyl-3-phenyl-propoxy)-1,3-dihydro-benzo[c]thiophene 2,2-dioxide 
• 86748-50-7 4-Phenyl-2-butyl O-Acetylmandelate 
• 101001-90-5 <2,2'-bipyridin>-6(1H)-one 

Relevant articles and documents

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Zwitterionic amidinates as effective ligands for platinum nanoparticle hydrogenation catalysts

Ligand control of metal nanoparticles (MNPs) is rapidly gaining importance as ligands can stabilize the MNPs and regulate their catalytic properties. Herein we report the first example of Pt NPs ligated by imidazolium-amidinate ligands that bind strongly through the amidinate anion to the platinum surface atoms. The binding was established by15N NMR spectroscopy, a precedent for nitrogen ligands on MNPs, and XPS. Both monodentate and bidentate coordination modes were found. DFT showed a high bonding energy of up to -48 kcal mol-1 for bidentate bonding to two adjacent metal atoms, which decreased to -28 ± 4 kcal mol-1 for monodentate bonding in the absence of impediments by other ligands. While the surface is densely covered with ligands, both IR and13C MAS NMR spectra proved the adsorption of CO on the surface and thus the availability of sites for catalysis. A particle size dependent Knight shift was observed in the13C MAS NMR spectra for the atoms that coordinate to the surface, but for small particles, ～1.2 nm, it almost vanished, as theory for MNPs predicts; this had not been experimentally verified before. The Pt NPs were found to be catalysts for the hydrogenation of ketones and a notable ligand effect was observed in the hydrogenation of electron-poor carbonyl groups. The catalytic activity is influenced by remote electron donor/acceptor groups introduced in the aryl-N-substituents of the amidinates; p-anisyl groups on the ligand gave catalysts several times faster the ligand containing p-chlorophenyl groups.

HYDROGEN TRANSFER REACTIONS FROM ALCOHOLS TO α,β-UNSATURATED KETONES: Cl, A VERY ACTIVE CATALYST PRECURSOR

A high catalytic activity, with turnover up to 900 cycles/min, is displayed by Cl in hydrogen transfer reactions from propan-2-ol to α,β-unsaturated ketones in a weakly alkaline medium.

Discovery and Redesign of a Family VIII Carboxylesterase with High (S)-Selectivity toward Chiral sec-Alcohols

Highly enantioselective lipase has been widely utilized in the preparation of versatile enantiopure chiral sec-alcohols through kinetic or dynamic kinetic resolution. Lipase is intrinsically (R)-selective, and it is difficult to obtain (S)-selective lipase. Recent crystal structures of a family VIII carboxylesterase have revealed that the spatial array of its catalytic triad is the mirror image of that of lipase but with a catalytic triad that is distinct from lipase. We, therefore, hypothesized that the family VIII carboxylesterase may exhibit (S)-enantioselectivity toward sec-alcohols similar to (S)-selective serine protease, whose catalytic triad is also spatially arrayed as its mirror image. In this study, a homologous enzyme (carboxylesterase from Proteobacteria bacterium SG_bin9, PBE) of a known family VIII carboxylesterase (pdb code: 4IVK) was prepared, which showed not only moderate (S)-selectivity toward sec-alcohols such as 3-butyn-2-ol and 1-phenylethyl alcohol but also (R)-selectivity toward particular sec-alcohols among the substrates explored. Furthermore, the (S)-selectivity of PBE has been significantly improved by rational redesign based on molecular modeling. Molecular modeling identified a binding pocket composed of Ser381, Ala383, and Arg408 for the methyl substituent of (R)-1-phenylethyl acetate and suggested that larger residues may increase the enantioselectivity by interfering with the binding of the slow-reacting enantiomer. As predicted, substituting Ser381with larger residues (Phe, Tyr, and Trp) significantly improved the (S)-selectivity of PBE toward all sec-alcohols explored, even the substrates toward which the wild-type PBE exhibits (R)-selectivity. For instance, the enantioselectivity toward 3-butyn-2-ol and 1-phenylethyl alcohol was improved from E = 5.5 and 36.1 to E = 2001 and 882, respectively, by single mutagenesis (S381F).

Enantioselective direct, base-free hydrogenation of ketones by a manganese amido complex of a homochiral, unsymmetrical P-N-P′ ligand

The use of manganese in homogeneous hydrogenation catalysis has been a recent focus in the pursuit of more environmentally benign base metal catalysts. It has great promise with its unique reactivity when coupled with metal-ligand cooperation of aminophosphine pincer ligands. Here, a manganese precatalyst Mn(P-N-P′)(CO)2, where P-N-P′ is the amido form of the ligand (S,S)-PPh2CHPhCHPhNHCH2CH2PiPr2, has been synthesized and used for base-free ketone hydrogenation. This catalyst shows exceptionally high enantioselectivity and good activity, with tolerance for base-sensitive substrates. NMR structural analysis of intermediates formed by the reaction of the amido complex with hydrogen under pressure identified a reactive hydride with an NOE contact with the syn amine proton. Computational analysis of the catalytic cycle reveals that the heterolytic splitting of dihydrogen across the MnN bond in the amido complex has a low barrier while the hydride transfer to the ketone is the turnover-limiting step. The pro-S transition state is found to be usually much lower in energy than the pro-R transition state depending on the ketone structure, consistent with the high (S) enantiomeric excess in the alcohol products. The energy to reach the transition state is higher for the distortion of the in-coming ketone than that of the hydride complex. In a one-to-one comparison with the similar iron catalyst FeH2(CO)(P-NH-P′), the manganese catalyst is found to have higher enantioselectivity, often over 95% ee, while the iron catalyst has higher activity and productivity. An explanation of these differences is provided on the basis of the more deformable iron hydride complex due to the smaller hydride ligands.

Synthetic ferripyrophyllite: Preparation, characterization and catalytic application

Sheet silicates, also known as phyllosilicates, contain parallel sheets of tetrahedral silicate built up by [Si2O5]2- entities connected through intermediate metal-oxygen octahedral layers. The well-known minerals talc and pyrophyllite are belonging to this group based on magnesium and aluminium, respectively. Surprisingly, the ferric analogue rarely occurs in nature and is found in mixtures and conglomerates with other materials only. While partial incorporation of iron into pyrophyllites has been achieved, no synthetic protocol for purely iron-based pyrophyllite has been published yet. Here we report about the first artificial synthesis of ferripyrophyllite under exceptional mild conditions. A similar ultrathin two-dimensional (2D) nanosheet morphology is obtained as in talc or pyrophyllite but with iron(iii) as a central metal. The high surface material exhibits a remarkably high thermostability. It shows some catalytic activity in ammonia synthesis and can serve as catalyst support material for noble metal nanoparticles.